Genetic background of sex determination; From sex determining gene to sex chromosome

Question 1

ploidy number in meoisis and fertilization

Answer 1

haploid (n)

diploid (2n)

Question 2

evolution of sex

Answer 2

asexual rep
sexual rep
production of haploid gametes
fusion-diploid zygote
parts of evolution: origin of sexual reproduction
evolution and maintenance

Question 3

what is sex

Answer 3

cyclic process between haploid and diploid type of cell

connection between cell types via meiosis generating the gamates and fertilization which will generate somatic cells

Question 4

Asexual rep- who does it

Answer 4

lower ranked organisms, unicellular, plants

Question 5

commons types of asexual reproduction in animals

Answer 5

1. fission (amoeba, plasmodium)
2. budding (hydra, sponges, corals)
3. regeneration (ex. worms, echinoderms)
4. fragmentation (sponges)
5. Parthenogenesis (honey bees, ants, wasps)
6. cloning (artifical method)

Question 6

only known vertebrate genus where partheogenesis occurs

Answer 6

cnemidophorus uniparents- only females

limited, reduced genetic diversity is typical

Question 7

How does a purely asexual lineage persist for millions of years in the face of changing environments and evolving parasites?

Answer 7

during evolution, their genes become very different, diversified
bdelloid homologous chromosomes have diverged to the point that most genes have only one functional copy
now they are locked into asexuality

Question 8

Advantages of asexuality

Answer 8

Avoids the two-fold cost of producing males.

No need to locate mates, an advantage at low density.

Maintains coadapted gene complexes, an advantage in stable environments.

Question 9

Disadvantages of asexuality

Answer 9

Deleterious mutation accumulation (Muller’s Ratchet) in small populations.

Time delay in acquiring optimal multilocus genotypes in changing environments.

Slow rate of evolution allows sexually reproducing antagonists (parasites, competitors, and predators) to get the upper hand.

Selective sweeps can eradicate all variation from a population.-any newly introduced variations would be harmful, will be eliminated/eradicated

Question 10

why have sex

Answer 10

recombination allows genetic variation

Question 11

two fold cost of sex

Answer 11

sexual reproduction= either 1 male or 1 female produced (ignore twins, triplets, etc)

asexual reproduction- double amount of females is produced then during sexual reproduction

Question 12

spectrum of mutations

Answer 12

is enormous, ranging from chromosomal rearrangements (translocations and inversions) and duplications to insertion and excisions of transposable elements to single base substitutions, insertions, and deletions

Question 13

vast majority of mutations appear to be…

Answer 13

deletions
slightly deleterious mutations are far more common than lethals

the input of slightly deleterious new mutation decreases population mean fitness by 1-2% each generation

Question 14

Mullers rachet

Answer 14

An asexual genome cannot produce offspring better than itself, except by rare back mutation.

The ratchet advances when the best class leaves no offspring, or if all of its offspring have acquired new deleterious mutations.

A mutational meltdown begins when the mutation load is so great that the populations is unable to replace itself.

Question 15

why sex is beneficial in relation to mullers ratchet

Answer 15

Recombination/sex is directly beneficial by purging deleterious mutations
Idea is that deleterious mutations affect the success of parthenogens - each generation new mutations increase the average genome contamination

Question 16

Hypotheses for the maintenance of sex (recombination)

Answer 16

carried out by the meiotic process and recombination of the homologous chromosomes

Question 17

“big benefit of sex’

Answer 17

Recombination provides a mechanism for genomic repair, eliminating deleterious mutations

parents can produce offspring that have higher fitness genotypes than themselves

Question 18

DNA repair hypothesis

Answer 18

Repair is only possible when a suitable template exists - homologues provide the template & repair involves crossing over
What’s less clear is whether DNA repair is the principle function of sex

Question 19

2 problems with the DNA Repair Hypothesis

Answer 19

1. Crossing over is absent in some circumstances (e.g., it is often absent in one sex), yet there is no obvious increase in mortality associated with repair
2. DNA repair should be greatest in environments where damage is highest, e.g., at high altitudes. However, parthenogenesis predominates in these habitats

Question 20

Fisher- Muller Hypothesis

Answer 20

Sex may facilitate response to environmental change by generating new gene combinations allowing populations to track a dynamic environment
This is because adaptive favorable mutations can be combined horizontally through a population

aka recombination spreads beneficial genes rapidly through a population

Question 21

Genetic Hitchhiking - long one sorry

Answer 21

newly arising beneficial mutations can occur on a chromosome that also contains a deletion

owing to recombination, beneficial alleles can fix on the X chromosome without dragging along linked deleterious mutations

on a non-recombining y chromosome, however, the fixation of the beneficial mutation will simultaneously fix the linked deleterious mutation

genetic hitchhiking requires that the selective advantage of the beneficial mutation outweights the effect of the linked deleterious allele - so that y chromosome containing the beneficial mutation has a non selective advantage

Question 22

long term benefit of sex

Answer 22

muller’s ratchet
population experiences greater genetic load of accumulated mutations

sex/recombin can help prevent mullers ratchet from turning, by allowing new combinations of alleles

flip side: beneficial combinations created as well

Question 23

Short term benefits of sex

Answer 23

red queen hypothesis

in the arms between hosts and parasites, there is constant, strong selection for new gene combinations

Question 24

what factors contributed to the rapid diversification of eukaryotic lineages

Answer 24

increased atmospheric O2 concentration- switch to aerobic respiration/

global climate change- major ice age around 2.7 BYA/

evolution of sexual rep.

Question 25

What is anisogamy in females and males

Answer 25

sexual reproduction by the fusion of dissimilar gamete

females: sex that produces few, well-provisioned gametes (eggs)
males: sex that produces many, ‘cheap” gametes (sperm)

Question 26

Summary of evolution sex- long one

Answer 26

Sexual reproduction (recombination) is a unique feature of eukaryotes and likely originated early in the history of this domain around ~2.7 BYA.

Increases in genome size and the proliferation of genome “parasites” may have favored the early evolution of recombination.

Asexuality avoids the “2-fold” cost of sex. Asexual lineages have both a genetic and demographic advantage over sexual lineages.

The effects of mutation accumulation in asexual lineages may offset these costs.

In stable environments, asexuality preserves well adapted genotypes and may be favored.

In contrast, in variable environments, sexual lineages may be capable of rapid adaptation and sex may be favored.

Question 27

Advantages of SEXUAL reproduction

Answer 27

high genetic variability
promotes adaptation
faster evolution

Question 28

Disadvantages of SEXUAL rep

Answer 28

energy consuming
courtship is energy-consuming and resource-demanding
usually it is at the expense of fitness of one of the sexes

Question 29

Advantages of ASEXUAL rep

Answer 29

energy saver
no courtship
highest fitness at the level of individuals

Question 30

Disadvantages of SEXUAL rep

Answer 30

small genetic variability
adaptation to the environment is difficult
slower evolution

Question 31

mechanisms of sex determination

Answer 31

Environmental 
Association with females
Egg size 
Incubation temperature 
Chromosomal 
Molecular basis 
Genic balance (X:A ratio)
Y linked genes

Question 32

Undifferentiated Gonad and Temperature

Answer 32

low aromatase activity
-high temp- high aromatase activity - ovary

-low temp- low aromtase activity- testis

Question 33

what is a hermaphrodites

Answer 33

a hermaphrodite is an organism that has reproductive organs normally associated with both male and female sexes.

Question 34

Genetic sex determination

Answer 34

sex is genetically determined- but no sex chromosomes

sex is still determined by genes - as in chromosomal sex determination, genes at one or more loci determine sex of individual

found in some plants and protozoans

Question 35

Haplodiploid sex determination

Answer 35

system determines
the sex of the offspring of many hymenopterans (bees, ants
and wasps). In this system, sex is determined by the number
of sets of chromosomes an individual receives. An offspring
formed from the union of a sperm and an egg develops as a
female, and an unfertilized egg develops as a male. This
means that the males have half the number of chromosomes
that a female has, and are haploid.

Question 36

how does X:A ratio influence gene expression

Answer 36

X:A ratio counting and sex lethal gene activation

XX:AA (1.0 ratio) sex lethal on- female

XY: AA (.5 ratio) sex lethal off- male

Question 37

late Sxl expression is regulated by

Answer 37

alternative mRNA splicing

Question 38

ZZ-ZW sex determination

Answer 38

ZZ-male, homogametic

ZW- female; heterogametic

Question 39

Haplodiploidy

Answer 39

unfertilized eggs- haploid set- male

fertilized eggs- diploid set- female

Question 40

possibilities for chromosome evolution:

Answer 40

duplications

translocations

Question 41

Sex defining genes

Answer 41

SRY
Sxl activity
xol-1 activity

Question 42

SRY

Answer 42

find on Y (so XY)
testis form
sex hormones- downstream genes- somatic sexual phenotype

Question 43

Sxl activity

Answer 43

splicing cascade
DSX-F in females
DSX-M in males

fru, dsf products

Question 44

xol-1

Answer 44

secreted proteins
females: HER-1
binding to receptor TRA-2

Question 45

X-encoded regulators

Answer 45

Sxl activity

xol-1 activity